Holt Stewart M, Scemama Jean-Luc, Panayiotidis Mihalis I, Georgakilas Alexandros G
Department of Biology, Thomas Harriot College of Arts and Sciences, East Carolina University, Greenville, NC 27858, USA.
Mutat Res. 2009 Mar 31;674(1-2):123-30. doi: 10.1016/j.mrgentox.2008.09.014. Epub 2008 Oct 7.
Ionizing radiation (IR) induces two classes of complex DNA damage, double-strand breaks (DSBs) and non-DSB bi-stranded oxidative clustered DNA lesions (OCDLs). OCDLs may consist of single strand breaks (SSBs), oxidized purines/pyrimidines and abasic sites within 5-10bp. These significant biological lesions are hypothesized to challenge the repair machinery and carry a high mutagenic potential. MSH2, a classical DNA mismatch repair protein, has been also implicated in other repair pathways associated with DSB and base lesion processing. MSH2 mutations have been identified in acute lymphoblastic leukemia (ALL) patients as well as in other types of cancers. Our research model involves two precursors B (pre-B) ALL human cell lines, NALM-6 cells, homozygous null for MSH2, and wild type 697 cells. Using a modified version of neutral and alkaline single cell gel electrophoresis (SCGE) with Escherichia coli repair enzymes as damage probes, the processing capacity of single strand breaks (SSBs), DSBs and OCDLs was assessed in NALM-6 and 697 cells exposed to a radiotherapy relevant gamma-ray dose of 5Gy. Using reverse transcriptase PCR and Western blotting we verified the complete lack of expression of MSH2 in the NALM-6 cells at the transcriptional and translational level. No differences were measured between NALM-6 and 697 cells in the induction levels of SSBs, DSBs and OCDLs after exposure to gamma-rays. However, 697 cells repaired each lesion more efficiently with significant differences observed after 1-3h post-irradiation. Lastly, our results indicate a significantly higher population of apoptotic 697 cells compared to NALM-6 cells 6-24h post-irradiation. Our studies suggest that MSH2 is probably involved in the processing of the biologically significant clustered DNA damages as well as the execution of apoptosis induced by ionizing radiation.
电离辐射(IR)会引发两类复杂的DNA损伤,即双链断裂(DSB)和非DSB双链氧化簇状DNA损伤(OCDL)。OCDL可能由单链断裂(SSB)、氧化嘌呤/嘧啶以及5 - 10个碱基对内的无碱基位点组成。据推测,这些严重的生物损伤会对修复机制构成挑战,并具有很高的诱变潜力。MSH2是一种经典的DNA错配修复蛋白,也参与了与DSB和碱基损伤处理相关的其他修复途径。在急性淋巴细胞白血病(ALL)患者以及其他类型的癌症中已发现MSH2突变。我们的研究模型涉及两种前体B(pre - B)ALL人类细胞系,即MSH2纯合缺失的NALM - 6细胞和野生型697细胞。使用改良版的中性和碱性单细胞凝胶电泳(SCGE),以大肠杆菌修复酶作为损伤探针,在暴露于5Gy放疗相关伽马射线剂量的NALM - 6和697细胞中评估单链断裂(SSB)、双链断裂(DSB)和OCDL的处理能力。通过逆转录聚合酶链反应(RT - PCR)和蛋白质免疫印迹法,我们在转录和翻译水平验证了NALM - 6细胞中完全不存在MSH2的表达。在暴露于伽马射线后,NALM - 6和697细胞在SSB、DSB和OCDL的诱导水平上未检测到差异。然而,697细胞对每种损伤的修复效率更高,在照射后1 - 3小时观察到显著差异。最后,我们的结果表明,照射后6 - 24小时,与NALM - 6细胞相比,凋亡的697细胞群体显著更多。我们的研究表明,MSH2可能参与了具有生物学意义的簇状DNA损伤的处理以及电离辐射诱导的细胞凋亡过程。
